Machine for making hollow glass articles



Jan. 5, 1943.

E. a. BRIDGES MACHINE FOR MAKING HOLLOW GLASS ARTICLES Filed Aug. 1, 1940 11 Sheets-Sheet 1 Z] w w cm/llm Edzvard ricgges,

5, 1943. E. G. BRIDGES 2,307,564

MACHINE FOR MAKING HOLLOW GLASS ARTICLES Jan. 5, 1943. E. G. BRIDGES MACHINE FOR MAKING HOLLOW GLASS ARTICLES 7 Filed Aug. 1, 1940 11 Sheets-Sheet 3 v. v 4 J I IN\\ I I l I .l HAM. My F NM. NM, w *m n QM- N N 5% q mb Rm km. R. NM. ANM

QN NW I nil-I'll II o msw mw a EN N mSN N gw W Rum MKWN @N. NMN o gm Nvfi kn NR Jan. 5, 1943. E. G. BRIDGES MACHINE FOR MAKING HOLLOW GLASS ARTICLES Filed Aug. 1, 1940 ll Sheets-Sheet 4 lg W 1943. E. G. BRIDGES I 2,307,564

MACHINE FOR MAKING HOLLOW GLASS ARTICLES Filed Aug. 1, 1940 ll Sheets-Sheet 5 jnva/wto'n likiward (ifir idqes 1943. E. G. BRIDGES 2,307,564

MACHINE FOR MAKING HOLLOW GLASS ARTICLES Filed Aug. 1, 1940 ll Sheets-Sheet 6 1: 5; 3 i w Fay- Jan. 5, 1943. E. G. BRIDGES MACHINE FOR MAKING HOLLOW GLASS ARTICLES 11 Sheets-Sheet 7 Filed Aug. 1, 1940 QQQ gin/120mm Edwanl$B ringy'es,

M- r s Jan. 5, 1943. E. G. BRIDGES 2,307,564

MACHINE FOR MAKING HOLLOW GLASS ARTICLES Filed Aug. 1, 1940 11 Sheets-Sheet 8 :1 v wc-wto'n v Edward GJBrirZges,

1943. E. G. BRIDGES 2,307,564

MACHINE FOR MAKING HOLLOW GLASS ARTICLES Filed Aug. 1, 1940 ll Sheets-Sheet 9 Edzvacl 126%}; 7 (lg/ A Jan. 5, 1943. E. G. BRIDGES MACHINE FOR MAKING HOLLOW GLASS ARTICLES Filed Aug. 1, 1940 ll Sheets-Sheet 10 0 7110102 I A Ii,

Edivard g Bric ige-s,

Jan. 5, 1943. E. G. BRIDGES MACHINE FOR MAKING HOLLOW GLASS ARTICLES Filed Aug. 1, 1940 ll Sheets-Sheet ll Patented Jan. 5, 1.943

MACHINE FOR MAKING HOLLOW' I ARTICLES Edward G. Bridges, Anderson, ma, asslgnor to Lynch Corporation, Anderson,

tion 01' Indiana Ind., a corpora- Application August 1, 1940,S erlal No. 349,108 22 Claims. (CI. 49-9) The present invention relates to improvements in glass blowing machines, particularly to machines for forming hollow glass containers, and

aims generally to improve existing machines for this purpose.

More specifically, the invention aims to improve machines of the general type shown in my prior Patent No. 2,049,422, granted August 4, 1936.

One of the more important objects of the present invention is to improve machines of the type and character of my prior Patent No. 2,049,422 by the provision of an improved motor driven drive mechanism for the mold carriers, and in this respect the present application is a continuation-in-part of myvprior copending application Serial No. 177,335, filed November 30, 1937.,

Another object of the invention is to improve the construction of means for applying suction to the parison molds for compacting the glass means and method of forming the parison and blowing the finished article to provide for a'better distribution of glass in the finished article to the end that strong usable articles may be made rapidly and economically.

Other objects of the invention will be apparent to those skilled in the art in view of the following more detailed description of the preferred embodiment of the invention which has been selected for illustrative purposes in the accompanying drawings.

In the draWings Fig. 1 is a skeleton plan view of the machine;

Fig. 2 is a central longitudinal sectional view of the parison mold carrier and its associated mechanism as taken on the line 2-2 of Fig. 1;

Fig. 3' is a similar view of the finishing mold carn'er andits associated mechanism as taken on the line 3-.3 of Fig. 1;

Fig. 4 is a horizontal sectional view taken on the line 4-4 of Fig. 2, portions of the base being broken away to illustrate the rotating mechanism for the parison mold carrier;

Fig. 5 is a detail sectional view taken on the line 55 of Fig. 4;

Fig. 6 is a similar view taken on the line 6-6 of 3, illustrating the base and rotating mechanism for the blow mold carrier;

Fig. 7 is an enlarged detail sectional view of thetransmission taken on the line ll of Fig. 6;

Fig. 8 is a detail sectional view taken on the line 88 of Fig. 7;

Fig. 9 is a transverse sectional view of the machine timer as taken on the line 9-9 of Figs. 1 and Fig. 10 is an end elevation'of the charge compacting mechanism at station A;

Fig. 11 is a sectional view thereof taken on the line HII of Fig. 10;

Fig. 12 is an enlarged sectional view of the counter-blowing air distributing chamber; I

Fig. 13 is an enlarged longitudinal sectional view of the blank mold opening mechanism;

Fig. 14 is a diagrammatic view illustrating the air line connections for operating the charge compacting devices; and

Fig. 15 is a diagrammatic view illustrating the air line connections for operating mold opening and closing and braking mechanisms of the ma chine.

The machine illustrated in the drawings is preferably of the so-called two table type, comprising laterally spaced parison and finishing mold carriers l0-l l rotatably mounted respectively upon central columns l2l3 fastened at their lower ends, as at M (Figs. 2 and 3), in a deep well l5 of a suitable base 16. The upper ends of the columns may carry collars ll bridged by a brace member l8.

Each mold carrier lll-'-|l is provided with its own driving mechanism, herein illustrated as a Geneva wheel l9, (Figs. 2, 3 and 4) and advantageously each mold carrier and its associated Geneva wheels are formed or connected together to provide a unitary structure surrounding the columns l2 or I 3 and rotatably supported thereon, on spaced anti-friction bearings 20.

For example, the mold carriers HIH may be formed'with an inner recess 2| (Fig. 3) and a central depending hub 22 having a radially extending flange 23 rigidly secured'as by bolts 24 and pins 24 to a central hub 25 of a Geneva wheel l9, formed with a plurality of slotted arms, one for each mold position in the tables l0l I. The assembled Geneva wheel' I 9 and mold carrier III are supported for rotation around the column 13 by. means of spaced anti-friction bearings 20, one of the bearings being interposed between the column l3 and the lower hub portion 25 of the Geneva wheel I 9, while the other anti-friction bearing is seated in the recess 2| of the'mold carrier around the central column. These antifriction bearings serve to .rotatably support the assembled mold-carrier l0 and Geneva wheel l9 as well as, to maintain them spaced from the column l3, providing an intervening oil space 26. An oil supply 21 may feed .oil to the ball ring of the upper bearing 26 which is in communication with the space 26. Cover plates 28 are fastened to the base l6 and have a central opening surrounding the hub portion 25 of the Geneva wheel providing closed lubricant chambers in the base for the Geneva wheels and associated driving mechanism.

A rotator 36 (Figs. 3 and 4) for each Geneva wheel is journalled in anti-friction bearings 3| in the base l6 and cover plates 218. Each-rotator 36 is preferably formed of a hollow casting formed with upper and lower trunnions 32, the major portion of the periphery of the casting being concentric with the trunnions 32. The casting includes an eccentric portion 33 carrying a pin 34 on which is rotatably mounted a driving block 35, preferably square in cross section, and adapted for engagement with the slots of the Geneva wheel l9 to impart intermittent rotation to the wheels and mold carriers |6| Secured to the upper surfaces of the rotator casting 36 is a worm wheel gear 36 in mesh with a driving worm 31 adapted to be coupled to a drive shaft. It will be noted, Fig. 3, that the worm gear 36 is cup-shaped and extends above the upper bearing 3|, so that the mesh between teeth of the worm 31 and worm gear 36 will be in the plane of the bearing, thus providing an extremely rigid mounting for the rotator, preventing binding between the rotator 36 and abutting concentric faces of the Geneva wheel l9.

Each driving worm 31 is rotatably mounted in its individual mounting 38 (Figs. 4 and secured within the base l6, so that the worm 31 and its mounting are replaceable as a unit. Referring to Figs. 3, 4 and 5, it will be noted that the worm mounting 38 is preferably in the form of a bracket having a machined face 39 and lateral extensions 46 providing shouldered seats for anti-frietion bearings 4| at opposite ends of the bracket. The worm 31 and its associated spindle 31 are shouldered as at 42 with reduced portions extending through the anti-friction bearings 4|, the adjacent outer portions of the spindle 37 being threaded for the reception of jam nuts 43 which may be pinned to the spindle 31. Thus the bearings 4| are clamped between shoulders 42 of the spindle 31* and the adjacent jam nuts 43 and the assembled spindle and bearing are clamped between the shouldered recess of the extension 46 and a clamping ring 44 bolted to one end face of one of the extensions 46. The worm mounting may be secured to the inner machined face of the base by means of a plurality of screws 45 acting to hold the mounting in its proper position.

To replace the worm 31 and its mounting with the rotator 36 and its associated worm gear 36, the cover 28 is first removed from the base. The screws 45 are then removed, permitting removal of the worm and its mounting as a unit, having first uncoupled the worm spindle 31 from the drive shaft. The entire rotator 36 may then be lifted vertically from the base for repair or replacement. The two worms 31 are connected together for rotation in unison by means of a drive shaft 46 coupled as at 41 to adjacent ends of the worm spindles 31 (see Figs. 4 and 6).

It will be noticed that the worm 31 for the two mold carriers ar oppositely threaded, that is; the worm 31 on the finishing mold carrier is left handed (Fig. 6) for indexing its Geneva rotor in a counter-clockwise direction, while the worm 31 for the parison mold carrier is right handed for indexing its Geneva rotor in a clockwise d1- rection. This results in the parison mold carrier being indexed counter-clockwise and the finishing mold carrier being indexed clockwise, so that an open parison mold with an exposed parison in it, and an open finishing mold, will approach the transfer position from the same side of the machine. I

Power driving means is preferably provided for rotating the worms and advantageously comprises an electric motor 56 connected through chain and sprocket-drive 5| to a variable speed transmission 52 adjustable to regulate the speed of the machine to a desired number of bottles per minute.

The variable speed transmission 52 is adapted to drive, through chain belt '53, a gear 54 (see Fig. '7) keyed as at 55 to a sleeve 56 loosely rotatable upon a jack shaft 51 rotatably mounted in bearings 58 in a transmission housing 59. The sleeve 56 is formed with an annular flange 66 secured to an overload clutch casing 6| loosely surrounding the shaft 51 so that clutch casing rotates at the same speed as the gear 54. v

The overload clutch casing is advantageously formedof two spaced discs 62 secured together by means of a plurality of bolts 63. Pivotally mounted within the housing 6| is a ratchet pawl 64 having an end seated in a ratchet recess 65' in ring 66 keyed to the jack shaft 51. The ratchet pawl 64 is normally held seated in the ratchet recess 65 by means of a spring 61 bearing against the opposite end, the compression of the spring being regulated by a plug 68 threaded into the housing 6|.

A second lever 69 preferably, a bell crank lever, is pivoted in the casing 6|, one leg of which overlies the pawl 64 and tends to hold the pawl in its ratchet recess. An adjustment spring 16 backed by a plug 1| threaded into the casing 6| exerts a predetermined pressure upon the pawl 64 to hold it in engagement with its recess.

Rotation of the casing 6| is in the direction of the arrow (Fig. 8). If the jack shaft 51 is subjected to an excessive load in excess of the load determined by the springs 61 and 16 the pawl 64 rocks on its pivot and out of engagement with the recess 65. When this happens, the end of the lever 69 is pressed against the ring 66' overlying the ratchet recess 65, permitting the machine to stop without damage. A reset plug 12 is provided for resetting the lever 69 to a released position, permitting pawl 64 to seat in ratchet recess 65.

Mounted on the jack shaft 51, within the transmission housing 59, is a gear 15 (see Fig. '1), in mesh with a gear 16 keyed as at 11 to a sleeve 18 loosely rotatable around the main shaft 19. One end of the sleeve is formed as a'cylindrical clutch housing 86 having a clutch face therein. A shiftable clutch member 8| on a sleeve 82, keyed to shaft 19 is movable into and out of engagement with the face of the clutch 86 by means of a clutch lever 83 fulcrumed at 84 and connected with a lever 85 for manually shifting the clutch; Power means in the form of a cylinder 86 having a piston 81 therein, the pistonrod 88 of which is connected to the clutch lever at 89 is also provided for operating the clutch as will be more particularly described hereafter. A stationary brake member 86 fastened to the trans mission casing is provided for engagement by the shiftable clutch to brake rotary movements of the machine and drive shaft when the clutch is disengaged.

The shaft may be coupled to the adjacent -vided with feeder timer shaft 93 or 94 (Figs. 6, '7 and 9). either for mechanically operated feeders or air operated feeders, respectively, for synchronizing the operation of a glass feeding device with the forming machine to insure that a chargeof glass will be delivered to the forming machine at the-charging station at the desired moment a mold is at that station to receive its charge. Ad vantageously the feeder timer shaft 93 or 94 is driven from a, continuously rotating part of the machine transmission, as for example the gear 16 and sleeve 18 (Fig. 7), while the forming machine timer 215 may be driven from the shaft I9 so as to rotate in synchronism with the indexing movements of the forming machine. g

The above described features of construction are of advantage in rotary glassware forming machines generally, and particularly those of the two-table or mold carrier type, regardless of the construction of fabricating devicesused for the shaping of the articles.

The invention, however, contemplates improvements in the method of and apparatus for manufacturing hollow container of the narrow-neck type, and in many respects is an improvement upon the method and apparatus shown in my prior Patent No. 2,049,422. According to the invention there is a series of invertible parison molds I on the carrier I 0 and a series of finishing or blow molds IN on the carrier II (see Fig. 1).

The parison molds I00 are designed to be presented in inverted or neck end down position at the charging station A, at which position the neck end of the mold is closed by a mouth forming pin mechanism (Fig. 11), so that the mold I00 may receive its charge of glass. At this position suction is applied to the neck mold and parison mold cavities to compact the charge around the mouthforming pin and initially form the neck or mouth end of the finished article. Optionally a compacting blow head may be applied to the upper open end of the mold to admit air under pressure to the top of the glass charge'to accelerate the compacting of the charge.

Thereafter the mouthforming pin is with-e drawn from the neck end of the parison mold and the machine is indexed to move the mold to the next station or mold position B. During this movement the bafile plate is applied to the upper open end of the mold I 00 so that air under pressure may be admitted to the mouth end of the compacted charge to counterblow or expand the charge in the closed parison mold and thus form a hollow preshaped parison of predetermined length. This counterblowing may start before the mold reaches position B and may continue until it reaches or is ready to leave position C. The parison mold is then reverted to upright or neck end up position during movement t 'po-. sition D, at which position the parison body molds are opened exposing the pre-formed parison suspended by the neck rings. The thus suspended parison is then moved to the transfer position E where a blow mold IOI on carrier II is closed around it. As the blow molds close around the parisons the neck rings are released therefrom so that the parison is free to move with the blow molds to a'reheating position F and final blowing positions G, H, I and J, and thence to the takeout or discharge position K. As the parison molds move from the transfer position E to the charging position A, they are first closed and later inverted to neck end down position.-

The parison molds and their mountings may I advantageously be of the type and construction shown in-my priorPatent No. 2,049,422 and comprise sectional mold halves mounted in holders I02 (see Figs. 2 and 11) pivotally mounted upon a hinge pin I03-in'an extensionv I04 of a mold support I 05 rotatable in anti-friction bearings I06 in supports I0! on the mold carrier I0.

The mold supports I05 are each rotatable about a horizontal axis. in the bearings I 06 and are hollow to lighten the construction and house the connections for opening and closing the molds at the proper time, which preferably include yoke members I09 embracing the hinge pin I03 and the adjacent sides of the molds and connectedtothe holders I02 at their opposed ends by links' I I0. The yoke members I09 are each slidable in a sleeve I I I 'journalled in themold support I05 (see Fig.2) carrying at its inner end a roller II2 on a pin and bearing upon the concentric lobe portion of a cam I I3 fixedly clampedto the parison mold support column I2. The in ward extension of the yoke is slidably connected to the sleeve III by a pin working in a slot in the 9 mounted on the; column I2 above the molds.

The rack member 8 is preferably placed to engage the pinions I I! of the mold supports during 3 movement of the mold between the third stop position C and the fourth stop position D so as to place the mold in its reverted or upright position preparatory to the opening of the mold. The second rack member II8- on the opposite side of the mold carrier engages the pinion III during mold movement toward the charging position to invert the mold prior to its being presented at that position.

Preferably, means for locking the mold in its respective upright positions is provided in the form of a locking pin I20 slidably mounted in an upper portion of the bearing support and normally urged inwardly by means of a spring into locking engagement with one of a pair of oppo-' sitely disposed locking pin seats in the rotatable mold support I05. The locking pin I20 is provided at its upper end with a roller I2I adapted when 'moved with the mold to engage a fixed cam trackway I22 on the support or bracket II9 to lift the locking pin I20 from its locking engagement with the seat in advance of the engagement of the pinion II! with the rack II8 so as to unlock the rotatable mold support and permit its rotation through by the rack member.

Associated with each parison mold is a neck mold I25 formed in sections and carried in neck ring holders I26 hingedly-mounted on the hinge pin I03 so that the neck mold cavity is in axial alignment with the parison mold cavity. I The neck mold sections are normally held together by means of a spring I21 (see Fig. 2) connected to pins I28 on each neck mold holder.

Associated with each neck ring holder is a combined suction and blowing unit and a mouthforming pin mechanism which may advantageously include a neck pin housing I30 (Figs. 2 and 11) carried by brackets I3I on the mold supports in alignment with the axis of the neck molds I25. Removably carried by the hous: ing I 30 is a guide member I32 on which is slidably mounted a stem I33 carrying a mouthforming pin I34 (Fig. 11) normally extending within the neck mold I25 so as to close the cavity therein. The stem I 33 is provided at its opposite end with a roller I35 and an offset pin I36, and a coiled spring I31 surrounding the guide I32 is interposed between the base of the guide and a washer I38 on the stem I33 so as to normally urge the mouthforming pin away from its closed position in the neck mold cavity.

Movement of the stem I33 and its associated mouthforming pin advantageously is controlled by a stem I39 on a piston I40 working in a vertically disposed cylinder I4I. As the parison mold is moved into charging position at position A,

air, controlled by valve 30I (Fig. 14) later described is admitted to the lower end of cylinder I4I to raise the piston I40 and th mouthforming pin to the cavity of the neck mold I25. Just prior to indexing the mold away from the charging position A, air is reversed in the cylinder to lower the'piston so that the yoke I42 overlying the pin I36 will withdraw the mouthforming pin from the neck mold cavity.

As each successive parison mold is moved into charging position, its mouthforming pin is raised to close the mouth end of the neck mold and as the mold is stopped to receive its charge, suction is applied in the parison mold to draw the charge quickly into the neck end thereof and compact it around the mouthf orming pin. One object of the invention is to improve the construction of the suction head for use with intermittently rotated machines.

According to the invention, a suction applying mechanism (see Figs. 2, 10 and 11), includes a bracket I46 mounted upon posts or standards I41 projecting vertically from the bed of the machine in position to register successively with the combined suction and blow head housing I30 of the neck molds as they are stopped at the charging station.

The bracket I46 carries a horizontally disposed air cylinder I48 having a piston I49 reciprocable therein, to the stem of which is carried a movable combined suction valve casing I50 and suction head I 45. The valve casing I50 preferably is hollow and has a suction inlet I5I communicating with the interior thereof. Above the inlet I5I is a. valve seat I52 adapted to be closed by a poppet valve I53, the stem of which extends downwardly throughthe bottom of the casing I50, being suitably packed against leakage. Above the valve seat is a suction conduit communicating with the suction head I so that when the valve I53 is raised above the seat, an unrestricted suction passage I54 is established from the head I45 to the inlet I5I. The valve I53 is normally held tightly against its seat I52 by a spring I55.

A valve operating cylinder I56 is removably attached to the lower end of the casing I and has a cupped piston I51 reciprocable therein engaging the lower end of the valve stem. When air is admitted to the lower end of th cylinder of air pressure past the piston I51 will escape through leakage port I59 and therefore cannot seep into the interior of casing I50 to destroy the efiect of the suction. As will be apparent when air is cut off from port I58, the valve will be instantly closed, due to the action of spring I55.

In the manufacture of certain types of ware it is advisable to additionally compact the glass charge in-the parison mold by means of air under pressure applied to the upper end of the charge. This advantageously may be accomplished by means of a blow head I60 mounted on the end of an arm I6I clamped to the upper end of rod I62 reciprocable through a guide I63 carried by the brackets I46, the lower end of the rod being fitted with a piston I64 in an air cylinder I65. The rod I62 extends downwardly beyond the piston I64 and cylinder I65 and is fitted with an ofiset roller I66 working in a cam slot I61 for the purpose of producing oscillation in the rod during reciprocation and thus swing the blow head I60 from a normal position axially removed from the mold to a closed position thereon. Axial reciprocations of the rod may be effected by alternately admitting air under pressure to opposite ends of the cylinder I65 through ports I 68-I69, controlled by valve 301 (Fig. 14) later described.

After the glass charge has been compacted in the parison mold, it is advisable to counterblow it to form a hollow parison of prede ermined length, and according to the invention, this counterblowing is relatively long and takes place during movement of the mold from position A to position B, and optionally until the mold leaves station C. Accordingly, this counterblow may be for one-half or more of the parison chilling or forming time, i. e. from charging at position A to blank mold opening at position D. The counterblowing of the parison is effected by admitting air under pressure to the mouth end of the parison while closing the upper open end of the mold by a baiile plate.

The bafiie plate I10 (see Fig. 1) is mounted upon one end of a bracket I1I pivotallymounted as at I12 upon the support I01 and normally held laterally removed from the axis of the mold by spring means I13 (Fig. 1). The opposite end of the bracket I1I carries a roller I14 adapted to engage a cam track I15 for swinging the baffle plate axially over the mold. As the mold moves away from its charging position at A, the baflle is swung over the mold and. a roller I16 on the upper face of the bracket I1I is moved under a cam I11 to lower the closure against the mold. The baflie plate remains on the mold during the stop period at position C and is removed as the mold leaves that position and just prior to reversion (see Fig. 1).

counterblowing air may be supplied to the mouth end of the parison by means of a rocker valve I80 (Fig. 2) having a passage I8I communicating with a cored passage I82 in the bearing I01 and a passage I83 in the mold support I05 communicating with the combined suction and blowing head I30 surrounding the mouth-forming pin in the manner disclosedin my prior I51 and valve stem will be raised. Any leakage Patent No. 2,049,422. v

Air is supplied to the valve I by means of a pipe line I84 (Figs. 2 and 12) extending into the mold carrier I0, opening into chamber I85 of the combined air and lubricant cap I86. The cap is formed with a tubular sleeve portion I81 surrounding column I2. and Is formed with an annular chamber I88 communicating with an air inlet port I89 in the column I2. An airtight packing is provided between the, sleeve I81 and the column I2 above and below the port I89 by means of packing rings I98 expanded against the sleeve I81 and column I2 by a spring I9I. The valve I88 is rocked to supply counterblowing air to the neck end of the parison by means of a pin I92 (see Figs. 2 and 4), adjustably mounted along the path of travel of the valve I88, preferably between stations A and B. Counterblowing preferably continues until the mold reaches station C or optionally as it leaves station C.

The valve I88 is operated to cut ofi counterblowing air by means of a stem I93 carried by a piston I94 movable in an air cylinder I95 (see Fig. 4) and mounted at station C in the path of the valve I88. Air may be supplied to the cylinder I95 as the parison mold is moved into station C, in which case the stem I93 is moved outwardly to engage and rock the valve I88 to closed position. Optionally air may be cut oif from cylinder I95, in which case the stem I93 acts as a stationary stop to rock valve I88 to closed position as the mold leaves station 0, insuring a longer counterblow.

As the parison molds leave position C, the baflle plate is first removed from the mold, and then the mold is rotated 180 about a horizontal axis to revert the mold to upright neck end up position. As the mold moves away from position C, the roller I14 on baille plate bracket I12 is moved from under cam I11 permitting bafile plaIe I1I to be raised from the mold. The roller I14 then rides on a relieved portion of cam I15, permitting spring I13 to swing bracket I12 and baffle plate axially away from the mold.

As the mold continues to travel toward position D, the pinion II1 on the mold support I85 engages a fixed rack II8 on the bracket H9 and rotates the mold 180 degrees in a manner well known in the art.

At position D the body blank portions of the parison mold are opened away from the preformed parison, leaving the exposed portion supported from the closed neck rings so that reheating of the chilled skin on the parison may start.

This is advantageously accomplished by means of an aircylinder I96 (Fig. 13) fixedly mounted on the machine frame at position D and in which is mounted a piston stem I91 carrying a yoke I98 adapted to engage a roller I99 on the sleeve III. As the mold is moved into position D, the roller I99 moves into the recess in the stem I98. Air is then supplied to the cylinder I96 to retract the stem and open the body blank portion of the mold.

As the body blank portions of the parison mold are removed from the parison, the heat of the glass in the interior of the parison gradually reheats the chilled skin. In intermittently rotated machines, operated by the mechanism disclosed herein the stop or rest period of the molds may equal or exceed the indexing or turning time, and may be of such duration, that the parison approaches a reheated condition while it is halted at position D. When the parison approaches such reheated condition, it has a tendency to stretch, and it must be shortened so that it may be received in the finishing mold. Accordingly, I provide a bottom former 288 (Fig. 14) at station D underlying the suspended parison and adapted to be moved vertically just prior to mold movement from position D to E. The vertical movement'advantageously may be accomplished with an air cylinder 28I having a piston 282 thereon, the stem of which carries the former 288.

As the mold moves from station D to E, the roller I99 moves inside a circular holding cam 289 (Flg. 2) which holds the mold sections open.

At position E the position of the parison suspended from the neck mold and the stopped position of the finishing mold are preferably coaxial. As the exposed parison is moved from pcsitlons D to E, a cooperating finishing mold on the carrier II is being moved toward position E from the same side of the machine, and is partially closed around the parison'as both arrive at the transferring position E.

The transfer of the parison to the finishing mold is completed at the transferring position E by final closing of the finishing molds and releasing or opening of the neck rings, so that the parison is wholly supported or confined in the finishing mold.

The construction of the finishing or blow molds I M their mounting, as well as the final blowing equipment may be of any approved construction and design, that shown being in substance like the corresponding mechanism of my prior Patent No. 2,049,422.

The finishing molds I8I (see Fig. 1), as stated above, are mounted upon the finishing mold carrier II and are movable in a closed path intersecting the path of the parison molds at the transfer position E and upon stopping at such position, the molds almost completely embrace the parison supported by the neck molds.

The finishing molds are preferably of the secfor opening and closing the finishing molds is essentially the same as applied to the opening of the parison molds, it need not be further described other than by general reference to the roller 2 resiliently connected by spring 2I2 with the' yoke 289 and adapted to engage the cam 2I3 (see Fig. 3), for holding the molds closed as desired. On approaching the transfer position, the molds I8I are gradually slowly closed by suitable mechanism (not shown here) so that the finishing molds close around the moving parisons as they approach the transfer position in unison. When the finishing mold reaches the transfer position, the roller 2 is moved within a fork 2I5 on a piston rod 2"; of a fluid pressure operated motor 2 I 1.

As will be explained hereafter, the fluid pressure motor 2I1. receives air pressure to actuate it in mold closing direction during the time that the mold is standing at the transferring position, and preferably this is timed to occur just following the disengagement of the neck rings from the parison. Radial outward movement of the fork 2I5 and the roller 2 to close the mold, positions the roller in line with the concentric lobe portion of the cam 2I3 so that upon the next succeeding movement of the mold away from transferring position, the mold is held tightly closed by reason of the engagement of the roller 2II upon the concentric lobe portion of the cam 2I3.

upper outer end of the bearing and having one of its ends slidably connected with the pin 220 of a yoke 22! slidably mounted upon the bearing 22 I and adapted to engage the pins I28 on the sectional neck ring holders. The opposite end of the lever 2|9 is positioned in front of a piston rod 10 222 of a fluid pressure operated motor 223 which is operated to actuate the bell crank lever MS as the neck mold comes into transfer position, and retract the yoke 22I causing, by reason of its as for example as shown in by Patent No. 2,049, 422, which may comprise suitable distributing valves 240 (see Fig. 3) one for each blowhead, and adjustably mounted upon a suitable support or frame consisting of a rim member '24! mounted at spaced intervals upon the standards 23! by means of suitable fastenings and preferably connected to a collector ring or hub 242 by means of arms fastened to the rim by screws or other suitable means. The valves 248 are preferably of the rocker type and are adapted to control the supply of blowing air from a suitable source,

' through the collector ring hub 242 and flexible engagement with the neck ring holders, the open-.

ing of the neck rings and the release of the parison into the finishing mold.

As is customary in the art, the finishing molds may be open at the bottom end and are adapted to be closed at the time of receiving the parison and during the final blowing of the articles therein by means of bottom plates 225 (see Fig. 3) removably held in bottom plate holders 226, the inner ends of which are vertically adjustable on guides 22'! pivoted to the mold support. The 25 lower end of each guide is preferably provided with a roller 228 adapted to roll upon a cam surface 229 carried by arcuate support 238 bolted to the bed frame of the machine and thus providing a cam surface for rocking the guides about their pivotal support and thus moving the bottom plates into and out of position to close the bottoms of the finishing molds at the desired time.

The brackets 208, providing mounting for the hinge pins 201 of the finishing mold holders, are formed each with an upwardly extending standard 23l having a lateral extension at its upper end providing a bearing for theupper end of a post 232, the lower end of which is secured in the upper portion of the bracket 208 preferably axially of the hinge pin 201. Individual blow head carriers 233 for each blow mold are slidably and rockably mounted upon the posts ing the post and formed with a laterally projecting arm terminating in a blow head adjustably mounted thereon, as in my prior Patent No. 2,049,422.

'- 232, each comprising a sleeve portion embrac- The sleeve portion of the blow head carrier is pivotally connected to a blow head operating lever 234 adapted to be operated to raise and lower the blow head at the proper time. The blow head is normally in its raised position laterally removed from the axis of the finishing er and actuated by a cam 236 fixed upon the ceneral column l3 of the blow mold carrier so that the pressure exerted upon the blow head in moving it toward th mold will be a resilient one, preventing serious damage and breakage to the exposed necks of the bottles, should the parts 7 not be properly aligned.

Admission of the blowing air to the blow head for blowing the bottle to its finished form may be controlled as to the time of starting, duration, volume and pressure by any suitable means,

conduits 243 from the collector ring to each of the valves 248. Flexible conduits are provided for connecting each of the valves 240 with its blow head.

Actuation of the valves 240 to admit blowing air to the blow head may be accomplished by means of a cam 241 (see Fig. l) pivoted to an arm 248 adjustably clamped upon the column l3 by suitable means, as for example a hand clamp.

As is apparent, the commencement of the final blowing may take place during mold movement between positions F and G or G and H as desired. It is desirable to continue the blowing air for as long as possible to facilitate cooling and settling of the article in the finishing mold. In the illustrated embodiment the final blowing operation is terminated by rocking the valve 240 back to its normal closed position, which is advantageously accomplished by means of an arm 249 adjustably clamped to the column [3 by a hand clamp and having an end lying in the path of the arm of the valves 248 to return the latter to normal closed position. Preferably the final blowing continues to station J.

Following the completion of the final blowing, the mold is moved to a takeout position K. Mounted on the cam 2 i3 in radial alignment with position K is a finishing mold opening cylinder 252 (see Fig. 3) having a piston 253 working therein. A piston rod 254 is connected to the piston 253 and has at its outer end a slide 255 movable with the piston rod 254.

As the finishing mold and roller are moved into position K, the roller-receiving fork of the slide 255 should be in its outer or extended position so as to receive roller 2| l. After the roller 2 has been positioned within the fork, air may be admitted to the outer end of the cylinder 252 to retract the piston 253 therein and fully open the mold ready for the takeout.

The finishing mold leaves position K in a fully opened position, and is moved to position L and then to transfer position, and during this'movement the molds are progressively closed around the moving parison, travelling from positions D to E as they jointly approach the transfer position E.

The control of the pneumatically operated devices of the machine, i. e. the fabricating devices, the mold opening and closing devices and the like, are advantageously by means of the machine timer 215 which preferably is of the rotary type driven by the driven shaft of the driving mechanism.

The timing mechanism (see Fig. 9) may advantageously comprise a base 216 adapted to be bolted to the housing 58. A transverse shaft 211 is journalled in the lower portion of the base, one end extending beyond the base and carrying the spiral gear 218 which meshes with the gear 213 on the sleeve 18 (see Figs. 7 and 9), the opposite end of the shaft 211, within the base, being fitted with a worm 288 meshing with a worm wheel 28I on a vertically disposed indicator shaft 282. Thus the indicator shaft rotates in synchronism and at the same speed as the feeder timer shafts as all are driven from the sleeve 18.

Surrounding the shaft 282 is a sleeve 283, to-

the lower end of which is secured a worm wheel 284 driven by a worm 285 on a shaft 286 jour'nalled in the base 216. One end of the shaft 286 extends beyond the base and into the housing 58 (Fig. 9) and carries a bevel gear 281 adapted to mesh with a bevel gear 288 keyed to the driven shaft 18 (see Fig. 7). Thus the sleeve 283 is geared to and rotates synchronously with the indexing operation of the forming machine, only when the shaft 18 is clutched to the driving sleeve 18 (Fig. -'1) Secured to the sleeve 288 is a timing drum 288 having a plurality of circumferential grooves 28I in which are adiustably mounted cams or buttons 282 adapted selectively to engage at proper times the stem 283 of the poppet valve 284 controlling the supply of air under pressure to various pneumatically operated parts of the forming machine.

Adjacent the upper end of the drum,the sleeve carries a gauge plate 285 which rotates therewith and which is surmounted by a pointer 286 fixed to the shaft 282 (see Fig. 9).

The cycle of operations may be best understood by considering the operations asthey take place starting withthe charging of the parison mold at the charging position A. It will be understood that the halted parison mold receives its charge of glass delivered from a feeding device, either mechanically operated or pneumatically operated and controlled by feeder timers 88 or 84 driven by the machine driving mechanism.

As the parison mold is halted at the charging position, it must be prepared to receive its charge of glass, and before such charge is delivered to the mold, the lower or neck end of the mold must be closed by the mouthforming pin. Accordingly the machine timer delivers a flash of air to line 388 (Fig. 14) leading to one end of plunger cylinder spool valve 38I to shift the valves toward the opposite end and permit the fiow of air under pressure from main air line M to line 382 leading to the lower end of cylinder I4I, to raise the piston I48 therein as well as the stem I33 and its associated mouthforming pin to close the mouth end of the mold.

Thereafter synchronously with the delivery of the glass charge to the parison mold, the machine timer 215 operates to deliver a flash of air to line 383 leading to one end of spool valve 384 to shift the valve toward the opposite end and thus permit the flow of air under pressure from.

main air line M to line 385 to supply air to the suction head, shifting cylinder I48 and the suction valve opening cylinder I56 to move the suction head I45 to the mold and open the suction valve I53 to apply suction to the interior of the mold to compact the charge.

A third air line 386 from the machine timer delivers a flash of air to one end of spiral blowdown spool valve 381 to shift the valve toward the opposite end and permit the flow of air under pressure from main air line M to line 388 leading to the upper end of spiral blowdown cylinder I65 to lower the piston I64 and move the blowhead I88 into engagement with the upper end of the mold for the additional compacting pressure. A cutofi cock 388 is positioned in line 386 and may be closed to prevent operation of the spiral blowdown when this operation is not desired.

The application of the compacting blowing air from the blowhead I68 is terminated by reversing spool valve 381 by means of air supplied to the opposite end of the valve through line 388 controlled by the machine timer 215. Reversal of valve 381 places line 388 on exhaust and admits air from main air line M to line 3I8, leading to the lower end of cylinder I to raise the blowhead. This line 388 also leads to the opposite end of suction head spool valve 384 to shift the valve in the opposite direction, placing line 385 on exhaust and allowing the springs to withdraw the suction head and close the valves I63, thus terminating the compacting of the charge. Similarly, a line 3 from machine timer 215 resets plunger cylinder spool valve 38I, placing line 382 on exhaust and establishing the flow of air from I main air line M to line 3I2 leading to the upper end of cylinder I to lower the piston therein and withdraw the mouthforming pin from its closed position with respect to the parison mold.

The operation of the bottom former 288 at sta-' tion D may take place synchronously with the application of the spiral blowdown and hence may be operated by spool valve 381 through lines 388" and 3I8 branching from lines 388 and 3I8, re-

spectively (see Fig. 14)

Some of the pneumatically operated devices of the machine, such as the parison mold opening cylinder I86 at position D; the neck mold opening cylinder 223 at position E; the finishing mold closing cylinder 2" at position E; and the finishing mold opening cylinder 252 at position K, all are operated in one direction only during the stop or halted periods of the molds and may be reset during succeeding indexing movements.

These devices advantageously may be controlled by a main operating valve 3I5 suitably mounted on the base of the machine which may be of the spool type, the valve being pneumatically controlled by lines 8I6, 3I1. controlled by the machine timer 215. Thus, after the molds have been indexed, the machine timer 215 supplies a flash. of air to line 3I6 leading to one end of the main parison mold opening cylinder to open the mold at position D; to actuate the-finishing mold closing cylinder to finally close the finishing mold around the parison at position E; to actuate the neck mold opening cylinder to open the neck mold at position E and to actuate the finishing mold opening cylinder to open the finishing molds at position K. Later, during indexing, the machine timer admits a flash of air to line 3I1 to reverse valve 3I5, placing line 3I8 on exhaust and establishing the flow of pressure air through line 3I8 to reverse motors I86, 2I1,- 223 and 252.

Suitable braking mechanism is provided for I mold carrier, comprising braking shoes 325 pivotally mounted at one end on' pins 326 secured to the base cover plate 28 and adapted to move in grooves 321 of the mold carriers. The opposite ends of pairs of shoes 325 are pivotally connected toan actuating linkage 328 (see Figs. 4 and 6) connected in turn to a rod 328 of a piston 338 working in an air cylinder 33I.

The pair of air cylinders 338 may be operated to apply and release the brakes by means of a brake cylinder valve 332 (Fig. 15) pneumatically connected .to the cylinder by air lines 333334 provided with exhaust ports, as is usual for exhausting air'from the 'lines 333 and 334 which are not under air pressure.

The operation of the valve is automatically controlled to apply the brake during the last half of the indexing movement as the mold carriers approach a stop period and advantageously this is controlled by the machine timer 215 by means of two valves 294 connected to lines 335 and 338 leading to opposite ends of valve casing 332. As

the valves 294 are controlled by buttons 292 adjustably mounted on the timer drum 296, the operation of the brake shoes 32!: may be variably adjusted to suit desired conditions.

Advantages of my invention reside in the provision of an improved machine for making hollow glass containers, particularly large and heavy ware at a high speed. Many machines are advantageously mechanically driven, and the mechanical drive according to my invention is admirably suited to hard and continuous usage without danger of breakage.

Furthermore, machines of the present invention have been demonstrated as capable of making a, larger variety of ware and in certain cases abetter grade of ware, than in the machine of my prior Patent No. 2,049,422.

means renders effective the full effect of the suc-' tion or vacuum pump which is not diminished by leakage of atmospheric air or pressure air from pneumatically operated machines.

Obviously the invention is not to be restricted to the details shown and described, but is intended to include equivalents as may fall within the scope of the appended claims.

I claim:

1. A machine for making hollow glass containers and the like comprising a circular series of parison molds and finishing molds, means for intermittently moving said molds in circular paths to a plurality of successive positions, a neck mold for cooperation with each parison mold, a mouthforming pin mechanism, means presenting said parison molds in succession in inverted position at a charging position to receive a charge of glass delivered from above said mold, means for applying fluid pressure differential on opposite ends of the glass charge to compact the charge therein and form a mouth finish on the parison, closure means for the mold for confining the charge therein, means for blowing the parison to hollow form while confined in the parison mold while the mold is moving to and is halted at two positions, at least, following the charging position, a reciprocable member mounted adjacent the mold at the second position following charging position and operable while the mold is halted for terminating the parison blowing at said station, means for thereafter inverting the parison to neck end up position, means for opening the parison mold away from the parison, means for transferring the parison to the finishing molds, and means for blowing the article to final form in the finishing mold.

2. A machine for making tainers and the like comprising a circular series of parison molds and finishing molds, means for intermittently moving said molds in circular paths to a plurality of successive positions, a neck mold for cooperation with each parison mold, a mouth-forming pin mechanism, means presenting said parison molds in succession in inverted position at a charging position to receive a charge of glass delivered from above said mold, means for applying fluid pressure differential on opposite ends of the glass charge to compact the charge therein and form a mouth finish on the parison, closure means for the mold for confining the charge therein, means for blowing the parison to hollow form while confined in the parison mold while the mold is moving to and is halted at two positions, at least, following the charging position, a reciprocable member mounted adjacent the mold at the second position following charging position and operable to terminate theparison blowing as the mold leaves said second position, means for thereafter inverting the parisonto-neck end up position, means for opening the parison mold away from the parison, means for transferring the parison to the finishing mold, and means for blowing the articleto final form in the finishing mold.

3. A machine for making hollow glass containers and the like comprising a circular series of parison molds and finishing molds, means for intermittently moving said molds in circular paths to a plurality of successive positions, a neck mold for cooperation with each parison mold, a mouthforming pin mechanism, means for presenting said parison molds in succession in inverted position at a charging position to receive a charge of glass delivered from above said mold, means for applying fluid pressure differential on ODDO-r site ends of the glass charge to compact the charge therein and form a mouth finish on the parison, closure means for the mold for confining the charge therein, means for blowing the parison to hollow form while confined in the parison mold while the mold is moving to and is halted at two positions, at least, following the charging position, fluid pressure operated means for terminating the parison blowing, means for thereafter inverting the parison to neck end up position, means for opening the parison mold away from the parison, means for transferring the parison to the finishing molds, and means for blowing the article to final form in the finishing mold.

4. A machine for making hollow glass containers and the like comprising a circular series of parison molds and finishing molds, means for intermittently moving said molds in circular paths to a plurality of successive positions, a neck mold for cooperation with each parison mold, a mouthforming pin'mechanism, means for presentin said parison molds in succession in inverted position at a charging position to receive a charge of glass delivered from above said mold, means for applying fluid pressure differential on opposite ends of the glass charge to compact the charge therein and form a mouth finish on the parison, closure means for the mold for confining the charge therein, means for blowing the parison to hollow form while confined in the parison mold while the mold is moving to and is halted at two positions, at least. following the charging P sition, means controlled independently of the movement of said molds for termnating the parison blowing operation, means for hollow glass conthereafter inverting the parison to neck end up position, means for opening the parison mold away from the parison, means for transferring the parison to the finishing molds, and means for blowing the article to final form in the finishing mold.

5. A machine for making hollow glass containers and the like com rising a circular series of parison molds and finishing molds, means for intermittently moving said molds in circular paths to a plurality of successive positions; a neck mold for cooperation with each parison mold, a mouthforming pin mechanism, means for presenting said parison molds in succession in inverted position at a charging position to receive a charge of glass delivered from above said mold, means for applying fiuid pressure differential on opposite ends of the glass charge to compact the charge therein and form a mouth finish on the parison, closure means for the mold for confining the charge therein, means for blowing the parison to hollow form while confined in the parison mold while the mold is moving to and is halted at two positions, at least, following the charging position, means controlled independently of the movement of said molds and operated by the mold moving means for terminating the parison blowing operation, means for thereafter inverting the parison to neck end up position, means for opening the parison mold away from the parison, means for transferring the parison to the finishing molds, and means for blowing the article to final form in the finishing mold.

' 6. A machine for making hollow glass containers and the like comprising a circular series of parison molds and finishing molds, mechanically driven means for intermittently moving said molds in circular paths to a plurality of successive positions, a neck mold for cooperationwith each parison mold, a timer operating in synchronism with said mechanically driven means, a mouthforming pin mechanism associated with said neck molds, means for presenting said parison molds in succession in inverted position at a charging position to receive a charge of glass delivered from above said mold, means for applying fluid pressure differential on opposite ends of the glass charge to compact the charge therein and form a mouth finish on the parison, closure means for the mold for confining the charge therein, means for blowing the parison to hollow form while confined in the parison mold during mold travel and throughout a distance substantially greater than the spacing between the molds, a reciprocable pneumatically operated device positioned at the second position following the charging position and pneumatic connections from said timer to said device, said device in one position being adapted to terminate the parison blowing as said mold is halted at said position and when in another position being operative to terminate said parison blowing as the mold leaves said second position following charging, means for thereafter inverting the pari son to neck end up position, means for opening the parison mold away from the parison, means for transferring the parison to the finishing molds, and means for blowing the article to final form in the finishing mold.

'7. In a machine for making hollow glass containers and the like, a mold carrier, a plurality of parison molds mounted thereon, cooperating neck molds for each parison mold, means for intermittently rotating said carrier to present said cooperating parison and neck molds successively to a charging position, and including time when determined by the duration a continuously rotating shaft, a timer geared to and operating in synchronism with said shaft, pneumaticaliv operated fabricating devices mounted adjacent the molds at the charging station and movable relative thereto for initially fabricating the glass charge in the mold while at the charging station, pneumatically operated control valves for controlling the supply of air to said pneumatically operated fabricating devices to move said devices in opposite directions and connections for delivering a flash 01' air from said timer to said control valves for positively positioning said control valves in operative position permitting the movement of said fabricating device to a selected position for a longer of the flash of air from said timer.

8. In a machine for making hollow glass containersand the like, a mold carrier, a plurality of parison molds mounted thereon, cooperating neck molds for each parison mold, means for intermittently rotating said carrier to present said cooperating parison andneck molds successively to a charging position, and including a continuously rotating shaft, a timer geared to and operating in synchronism with said shaft, pneumatically operated fabricating devices including mouth pin mechanism and suction applying mechanism mounted adjacent the molds at the charging station and movable relative'thereto for initially fabricating the glass charge in the mold while at the charging station, pneumatically operated control valves for controlling the supp y of air to said pneumatically operated fabricating devices to move said devices in opposite directions, and connections for delivering a flash of air from said timer to said control valves fo positively positioning said control valves in operative position permitting the movement of said fabricating device to a selected position for a longer time than determined by the duration of the flash of air from said timer.

9. In a machine for making hollow glass containers and the like, a mold carrier, a plurality of parison molds mounted thereon, cooperating neck molds for each parison mold, means for intermittently rotating said carrier to present said cooperating parison and neck molds successively to a charging position, and including a continuously rotating shaft, a timer geared to and operating in synchronism with said shaft, pneumatically operated fabricating devices including mouth pin mechanism and charge compacting mechanism mounted adjacent the molds at the charging station and movable relative thereto for initially fabricating the glass charge in the mold while at the charging station, pneumatically operated control valves for controlling the supply of air to said pneumatically operated fabricating devices to move said devices in opposite directions, and connections-for delivering a flash of air from said timer to said control valves for positively positioning said control valves in operative position permitting the movement of said fabricating devices to a selected position for a longer time than determined by the duration of the flash of air from said timer.

10. In a glassware shaping machine, a rotary mold carrier, a plurality of molds thereon, means for intermittently rotating said carrier to present said molds successively to a glass shaping station, means mounted at said station for engaging said molds for applying suction thereto, said last named means comprising a horizontally movable suction-applying head having a passage 

